Soil Influence on Forest Vegetation Productivity and Patterns in the Eastern Cascades of Southern Oregon

Thesis (Master's)--University of Washington, 2016-06

The effect of land management on plant community composition, species diversity, and productivity of alpine Kobersia steppe meadow

Grassland degradation is widespread and severe on the Tibet Plateau. To explore management approaches for sustainable development of degraded and restored ecosystems, we studied the effect of land degradation on species composition, species diversity, and vegetation productivity, and examined the relative influence of various rehabilitation practices (two seeding treatments and a non-seeded natural recovery treatment) on community structure and vegetation productivity in early secondary succession. The results showed: (1) All sedge and grass species of the natural steppe meadow had disappeared from the severely degraded land. The above-ground and root biomass of severely degraded land were only 38 and 14.7%, respectively, of those of the control. So, the original ecosystem has been dramatically altered by land degradation on alpine steppe meadow. (2) Seeding measures may promote above-ground biomass, particularly grass biomass, and ground cover. Except for the grasses seeded, however, other grass and sedge species did not occur after seeding treatments in the sixth year of seeding. Establishment of grasses during natural recovery treatment progressed slowly compared with during seeding treatments. Many annual forbs invaded and established during the 6 years of natural recovery. In addition, there was greater diversity after natural recovery treatment than after seeding treatments. (3) The above-ground biomass after seeding treatment and natural recovery treatment were 114 and 55%, respectively, of that of the control. No significant differences in root biomass occurred among the natural recovery and seeded treatments. Root biomass after rehabilitation treatment was 23-31% that of the control.

Global vegetation and terrestrial carbon cycle changes after the last ice age

•In current models, the ecophysiological effects of CO2 create both woody thickening and terrestrial carbon uptake, as observed now, and forest cover and terrestrial carbon storage increases that took place after the last glacial maximum (LGM). Here, we aimed to assess the realism of modelled vegetation and carbon storage changes between LGM and the pre-industrial Holocene (PIH). •We applied Land Processes and eXchanges (LPX), a dynamic global vegetation model (DGVM), with lowered CO2 and LGM climate anomalies from the Palaeoclimate Modelling Intercomparison Project (PMIP II), and compared the model results with palaeodata. •Modelled global gross primary production was reduced by 27–36% and carbon storage by 550–694 Pg C compared with PIH. Comparable reductions have been estimated from stable isotopes. The modelled areal reduction of forests is broadly consistent with pollen records. Despite reduced productivity and biomass, tropical forests accounted for a greater proportion of modelled land carbon storage at LGM (28–32%) than at PIH (25%). •The agreement between palaeodata and model results for LGM is consistent with the hypothesis that the ecophysiological effects of CO2 influence tree–grass competition and vegetation productivity, and suggests that these effects are also at work today.

Global patterns of vegetation response to millennial-scale variability and rapid climate change during the last glacial period

Ninety-four sites worldwide have sufficient resolution and dating to document the impact of millennial-scale climate variability on vegetation and fire regimes during the last glacial period. Although Dansgaard–Oeschger (D–O) cycles all show a basically similar gross structure, they vary in the magnitude and the length of the warm and cool intervals. We illustrate the geographic patterns in the climate-induced changes in vegetation by comparing D–O 6, D–O 8 and D–O 19. There is a strong response to both D–O warming events and subsequent cooling, most marked in the northern extratropics. Pollen records from marine cores from the northern extratropics confirm that there is no lag between the change in climate and the vegetation response, within the limits of the dating resolution (50–100 years). However, the magnitude of the change in vegetation is regionally specific and is not a simple function of either the magnitude or the duration of the change in climate as registered in Greenland ice cores. Fire regimes also show an initial immediate response to climate changes, but during cooling intervals there is a slow recovery of biomass burning after the initial reduction, suggesting a secondary control through the recovery of vegetation productivity. In the extratropics, vegetation changes are largely determined by winter temperatures while in the tropics they are largely determined by changes in plant-available water. Tropical vegetation records show changes corresponding to Heinrich Stadials but the response to D–O warming events is less marked than in the northern extratropics. There are very few high-resolution records from the Southern Hemisphere extratropics, but these records also show both a vegetation and fire response to millennial-scale climate variability. It is not yet possible to determine unequivocally whether terrestrial records reflect the asynchroneity apparent in the ice-core records.

Assessing the mitigation potential of forestry activities in a changing climate: A case study for Karnataka

The Clean Development Mechanism (CDM), Article 12 of the Kyoto Protocol allows Afforestation and Reforestation (A/R) projects as mitigation activities to offset the CO2 in the atmosphere whilst simultaneously seeking to ensure sustainable development for the host country. The Kyoto Protocol was ratified by the Government of India in August 2002 and one of India's objectives in acceding to the Protocol was to fulfil the prerequisites for implementation of projects under the CDM in accordance with national sustainable priorities. The objective of this paper is to assess the effectiveness of using large-scale forestry projects under the CDM in achieving its twin goals using Karnataka State as a case study. The Generalized Comprehensive Mitigation Assessment Process (GCOMAP) Model is used to observe the effect of varying carbon prices on the land available for A/R projects. The model is coupled with outputs from the Lund-Potsdam-Jena (LPJ) Dynamic Global Vegetation Model to incorporate the impacts of temperature rise due to climate change under the Intergovernmental Panel on Climate Change (IPCC) Special Report on Emissions Scenarios (SRES) A2, A1B and B1. With rising temperatures and CO2, vegetation productivity is increased under A2 and A1B scenarios and reduced under B1. Results indicate that higher carbon price paths produce higher gains in carbon credits and accelerate the rate at which available land hits maximum capacity thus acting as either an incentive or disincentive for landowners to commit their lands to forestry mitigation projects. (C) 2009 Elsevier B.V. All rights reserved.

Trends and Variability of AVHRR-Derived NPP in India

In this paper, we estimate the trends and variability in Advanced Very High Resolution Radiometer (AVHRR)-derived terrestrial net primary productivity (NPP) over India for the period 1982-2006. We find an increasing trend of 3.9% per decade (r = 0.78, R-2 = 0.61) during the analysis period. A multivariate linear regression of NPP with temperature, precipitation, atmospheric CO2 concentration, soil water and surface solar radiation (r = 0.80, R-2 = 0.65) indicates that the increasing trend is partly driven by increasing atmospheric CO2 concentration and the consequent CO2 fertilization of the ecosystems. However, human interventions may have also played a key role in the NPP increase: non-forest NPP growth is largely driven by increases in irrigated area and fertilizer use, while forest NPP is influenced by plantation and forest conservation programs. A similar multivariate regression of interannual NPP anomalies with temperature, precipitation, soil water, solar radiation and CO2 anomalies suggests that the interannual variability in NPP is primarily driven by precipitation and temperature variability. Mean seasonal NPP is largest during post-monsoon and lowest during the pre-monsoon period, thereby indicating the importance of soil moisture for vegetation productivity.

植被生产力与植物克隆性的样带分析

克隆植物存在于自然界几乎所有类型生态系统，在群落和生态系统中起着重要作用。作为植物群落的重要组分，克隆植物势必深刻地影响群落的结构和功能。揭示克隆植物在不同类型生态系统中的重要性及其与环境因子的关系是克隆植物生态学研究的重要内容。 本研究以东北样带为平台，通过采用野外植物和土壤调查，结合2006年23期500 m MODIS NDVI数据，重点分析环境因素和群落生产力与克隆植物丰富度和重要性的关系。主要结论如下： 1．沿东北样带自西向东的不同植被类型中，克隆植物出现的频率和重要值呈现降低的趋势，具体体现为：典型草原 > 荒漠草原 > 草甸草原 > 农田 > 森林。克隆植物丰富度、重要值和相对物种数均与海拔呈显著相关，但这种关系随克隆构型发生变化。 2．群落中克隆植物物种丰富度与土壤有机碳、全氮和全磷均有显著的相关关系，但与全钾并不呈现显著相关关系。通径分析表明，在三种草原植被中，土壤成分对克隆植物重要性的影响强度随草原类型变化而变化。 3．植被生产力与年均降水量和年均日照时数显著相关;虽然植被生产力与年均温度没有显著的相关性，但与温度季节性变化呈显著相关;植被生产力与降水和温度季节性的相关性随植被类型发生变化。 4. 就整个东北样带而言，植被生产力与群落中总的物种丰富度和克隆植物丰富度呈显著正相关，但与不同克隆构型克隆植物的丰富度相关关系不一致。在不同植被类型中，生产力与克隆植物丰富度没有相关关系，但与克隆植物重要值呈现不同相关关系。具体而言，克隆植物重要值与植被生产力的相关性在荒漠草原表现为正相关，在典型草原和草甸草原呈负相关，而在农田和森林没有显著相关性。 在土壤环境相对贫瘠和植被生产力水平较低的条件下，克隆植物可能比非克隆植物具有更强的适应能力，并在群落次生演替过程中起重要作用。在高海拔、养分贫瘠的群落中，克隆植物出现频率较高。在荒漠草原，由于土壤贫瘠、扰动频繁，因此克隆植物在群落中的重要性较高，在生产力水平高的植物群落中克隆植物重要性较高;在典型草原和草甸草原，由于土壤养分等条件的改善，克隆植物在群落中的重要性降低，在生产力水平高的植物群落中克隆植物重要性较低;在农田和森林群落中，环境质量最好，克隆植物在群落中的重要性低，对群落的结构和生产力不构成显著影响，因此克隆植物重要性与生产力相关性不显著。

辽河三角洲植被结构、功能及其驱动机制

辽河三角洲优越的植被生态系统维系着多种生态功能，使该地区成为全国著名的商品粮基地、造纸原料基地和旅游基地。但是，气候变化和人为干扰使得辽河三角洲的植被结构发生了显著变化，影响到植被功能的发挥。 为了应对气候变化和人为干扰对辽河三角洲植被造成的不利影响，本论文围绕植被结构和生产功能，从空间和时间方面，重点阐述了辽河三角洲植被的结构及其驱动机制；辽河三角洲植被生产功能及其驱动机制。 采用的研究方法包括遥感解译、样带调查和全面调查。通过遥感解译方法获取各植被类型的面积、分布及其变化信息，以研究植被的空间分布格局及其变化。通过样带调查方法，获取植被类型、土壤和水文等信息，并结合规范对应分析和偏相关分析等，研究植被空间分布格局的驱动机制。通过全面调查方法，获取植被净第一性生产力、粮食产量、土壤和水文等信息，并结合地理信息系统(GIS)的插值分析和相关分析等，研究植被生产功能的空间分布格局及其驱动机制。主要结论如下： 1. 植被组成和空间格局：辽河三角洲植被主要由自然湿地植被、人工湿地植被、自然旱地植被、人工旱地植被四大植被类型组成。其中，面积最大的3种植被是玉米、水稻和芦苇。四大植被类型以双台子河口为中心，基本上呈现半环状分布格局。 2. 植被空间格局变化：1988～2006年辽河三角洲植被空间格局发生了显著变化，主要植被类型分布趋于集中，形成了一些较大的斑块，而不是离散和破碎。从面积上看，水稻是面积增加最多的植被类型；玉米是面积减少最多的植被类型。从变化速率看，水稻、玉米和芦苇的变化幅度都较大，分别为33.2%、-16.1%和-23.2% 。 3. 植被空间格局形成机制：辽河三角洲植被分布格局不是由气候因子决定的，而是由土壤因子决定。土壤可溶性盐是决定植被分布格局最重要的环境因子，其次是土壤含水量。 4. 植被生产功能：辽河三角洲植被具有极高的生产力。其中，玉米、水稻和芦苇3种主要植被的地上净第一性生产力分别为30,485、18,248和17,440 kg/(ha•a)。玉米和水稻单位面积粮食产量也非常高，分别为14,813和10,365 kg/(ha•a)。 5. 植被生产功能年际变化：辽河三角洲植被生产力存在明显的年际波动。1992～2005 年间玉米和水稻粮食产量呈现显著的年际波动；1949～1990 年间芦苇产量不仅存在较明显的年际波动，而且呈现非常显著的增加趋势。 6. 植被生产功能年际变化的驱动机制：气候因子是玉米和水稻粮食产量年际变化的主要驱动因子，气候因子对玉米和水稻粮食产量的影响远远大于人为因子（农业人口、施肥量、灌溉面积）的影响。气候因子和人为因子对芦苇产量年际变化的影响都非常显著。在气候因子中，年日照数是驱动玉米产量年际波动的主导气候因子；年降水量是驱动水稻产量年际波动的主导气候因子；年蒸发量是驱动芦苇产量年际波动的主导气候因子。 7. 植被生产功能空间格局：植被地上净第一性生产力存在显著的空间差异，表现为一种环形空间分布格局，三角洲中部较低，四周地区较高。这种空间分布格局表明，在辽河三角洲，植被地上净第一性生产力最高的不是湿地植被，而是周围旱地植被。 8. 植被生产功能空间格局的形成机制：土壤含水量和海拔是驱动辽河三角洲植被生产力空间格局的主要因子；土壤盐度、土壤pH和土壤容重对植被生产力的空间格局影响不大。土壤营养元素(氮、磷、钾) 对植被生产力的空间格局几乎没有影响。

黄土丘陵区流域生物量和气体调节服务功能价值动态变化及评价

文章研究纸坊沟流域内草地、农地、林地、灌丛四种不同生态系统类型植被生产力及逐年生物量,估算各生态系统类型固定CO2和释放O2的能力,并根据生态学原理和生态经济学方法,运用碳税法、造林成本法和影子价格法,推算出各生态类型固定CO2和释放O2气体的生态、调节服务功能价值。研究表明,1985～2001年流域总生物量年均生物量和总体呈线性增加趋势。由于各种治理措施的实施和退耕还林(草)政策的正确导向,纸坊沟流域土地利用趋于合理,CO2/O2气体调节服务功能价值逐步增强,流域生态经济系统向良性演变。不同生态系统类型气体调节功能价值的估算为退耕还林(草)年限及生态补偿提供了科学决策依据。

Implantação de planos de fogo controlado na gestão dos recursos alimentares para cavalos da raça Garrana em Valença

Dissertação apresentada à Escola Superior Agrária do Instituto Politécnico de Castelo Branco para cumprimento dos requisitos necessários à obtenção do grau de Mestre em Tecnologias e Sustentabilidade dos Sistema Florestais.

Effect of plateau zokors on vegetation characteristics and productivity of alpine meadow

This research was conducted on alpine meadow site at Menyuan county, Qinghai Province, People's Republic of China to determine the effects of native, subterranean rodent of Qinghai-Tibet grasslands, the plateau zokors (Myospalax baileyi), on seasonal above-and below-ground plant biomass, plant species diversity and productivity. Both total peaks of above-and below-ground biomass were the greatest (413.600 g/m~2 and 2297.502 g/m~2) in the patch no any plateau zokors colonized by plateau zokors over 10 years in August and October, respectively. Both above-and below-ground biomass were significantly increased in the patches where plateau zokors were removed or the burrow systems were abandoned for five years compared to the patches plateau zokors colonized over 10 years. However, both above-and below-ground biomass in abandoned patches were significantly lower than that in uncolonized patches. Monocotyledonous biomass was reduced greatly, but the non-palatable dicots were significantly increased in colonized patches. The palatable biomass of monocots and dicots were increased in abandoned patches. Total plant species diversity was the greatest in uncolonized patchesand least in abandoned patch. The total net primary production in colonized patches was reduced by 68.98% compared with uncolonized patches. Although the patches were without any plateau zokors disturbance for fives years, the total net primary production just reached 58.69% of the uncolonized patches. The above-ground net primary production in abandoned patches increased 28.74% and the below-ground increased 54.91% compared with the colonized patches. We suggest that plateau zokor-induced changes in plant above- and below-ground biomass and species diversity may lead to further alterations of nutrient cycling and trophic dynamics in this alpine meadow ecosystem.

Net primary productivity and spatial distribution of vegetation in an alpine wetland, Qinghai-Tibetan Plateau

To initially describe vegetation structure and spatial variation in plant biomass in a typical alpine wetland of the Qinghai-Tibetan Plateau, net primary productivity and vegetation in relationship to environmental factors were investigated. In 2002, the wetland remained flooded to an average water depth of 25 cm during the growing season, from July to mid-September. We mapped the floodline and vegetation distribution using GPS (global positioning system). Coverage of vegetation in the wetland was 100%, and the vegetation was zonally distributed along a water depth gradient, with three emergent plant zones (Hippuris vulgaris-dominated zone, Scirpus distigmaticus-dominated zone, and Carex allivescers-dominated zone) and one submerged plant zone (Potamogeton pectinatus-dominated zone). Both aboveground and belowground biomass varied temporally within and among the vegetation zones. Further, net primary productivity (NPP) as estimated by peak biomass also differed among the vegetation zones; aboveground NPP was highest in the Carex-dominated zone with shallowest water and lowest in the Potamogeton zone with deepest water. The area occupied by each zone was 73.5% for P. pectinatus, 2.6% for H. vulgaris, 20.5% for S. distigmaticus, and 3.4% for C. allivescers. Morphological features in relationship to gas-transport efficiency of the aerial part differed among the emergent plants. Of the three emergent plants, H. vulgaris, which dominated in the deeper water, showed greater morphological adaptability to deep water than the other two emergent plants.